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Programmable Switch as a Parallel Computing Device

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arxiv 1803.01491 v1 pith:Y2SVN4BZ submitted 2018-03-05 cs.NI cs.DC

Programmable Switch as a Parallel Computing Device

classification cs.NI cs.DC
keywords computationdataparallelcapacitycomputingnetworkoffloadingp4mr
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Modern switches have packet processing capacity of up to multi-tera bits per second, and they are also becoming more and more programmable. We seek to understand whether the programmability can translate packet processing capacity to computational power for parallel computing applications. In this paper, we first develop a simple mathematical model to understand the costs and overheads of data plane computation. Then we validate the the performance benefits of offloading computation to network. Using experiments on real data center network, we finnd that offloading computation to the data plane results in up to 20x speed-up for a simple Map-Reduce application. Motivated by this, we propose a parallel programming framework, p4mr, to help users efficiently program multiple switches. We successfully build and test a prototype of p4mr on a simulated testbed.

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